RU177130U1 - INSULATING FACING PLATE - Google Patents

Abstract

The utility model relates to building elements of relatively small thickness for the construction of individual parts of buildings, for example, slabs, panels consisting of insulating material and concrete, in particular to heat and sound insulating plates for wall cladding. Facing insulating plate includes interconnected insulating layer made of heat-insulating material, and a decorative protective layer made of fiber-reinforced concrete based on sand, cement binder and polymer additives. In the protective and decorative layer, all side surfaces along the entire thickness of the layer from the inner surface to the outer one are beveled at an angle of 80-85 ° to form a compensation indent. In the decorative protective layer on the outer surface, installation recesses can be made. Fiber-concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, as a binder may additionally contain hydrated lime. Fiber-concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, may additionally contain sodium laureth sulfate or sodium lauryl sulfate.

Description

The utility model relates to building elements of relatively small thickness for the construction of individual parts of buildings, for example, slabs, panels consisting of insulating material and concrete, in particular to heat and sound insulating plates for wall cladding.

A known insulating facing slab adopted as the closest analogue is described in the patent of the Russian Federation No. 169086 for the utility model “Decorative facing decorative slab”, IPC E04C 2/288, 2017. The device according to the closest analogue is a two-layer plate. One layer of insulating plate performs the function of thermal insulation of the facade of the building and is a rigid sheet of heat-insulating material (polystyrene foam, mineral wool, etc.), the thickness of which (3-5 cm) depends on the climatic conditions of operation of the facade. The second layer of the slab, decorative and protective, performs aesthetic functions and protects the insulating layer from external atmospheric and other influences and is a layer of cement-sand fiber concrete with polymer additives, that is, a layer which includes cement as a binder, as well as sand and polymer additives. The layer is reinforced with fiberglass using a polymerizing additive (for example, polyvinyl acetate) and a plasticizer (for example, C-3 manufactured by Moscow Polyplast OJSC). Additionally, it contains alkali metal lauryl sulfate, sodium lauryl sulfate can be used as alkali metal lauryl sulfate. The thickness of the second layer of the plate (1.0-2.0 cm) depends on the configuration of the texture pattern. In the manufacturing process of the plate, both layers are interconnected, ensuring their strong permanent connection. An insulating cladding plate is made - the closest analogue - by vibration casting into a mold.

It is known that

concrete - an artificial building material obtained by molding and solidifying a rationally selected and compacted mixture consisting of a binder (cement - an artificial inorganic hydraulic binder or other binder), large and small aggregates, water, and in some cases containing special additives ;

fiber - micro-reinforcement, evenly reinforcing concrete in all planes, increasing the concrete grade, strength, impact resistance and reducing the formation of shrinkage cracks;

fiber - any fibrous filler for concrete reinforcement;

fiber-reinforced concrete is a high-tech material, a type of concrete in which fiber and / or fiber are evenly distributed as a reinforcing material.

Also, in the form of polymer additives in a concrete or mortar mixture, polymeric materials are used for the following purposes: as an additional cementitious component, for impregnation of concrete and reinforced concrete products, for the production of dry construction mixtures, as a microfiller, for dispersed reinforcement with polymer fibers. To increase the deformation characteristics of concrete and mortars, dispersed reinforcement with polymer fibers is effective as polymer additives. Fiber and fiber are used in all structures where it is necessary to prevent the appearance of plastic shrinkage cracks. For dispersed reinforcement, polymer additives are used - polypropylene fiber, intended for use in cement systems. This is an inert material, resistant to acids, alkalis and salts, with high ability to mix and the property of uniform distribution of fiber in concrete ("Builder's Guide. Additives that give concrete special properties", http://baurum.ru/_library/?cat= additives_special_properties & id = 320).

A plate consisting of a layer of sheet heat-insulating material, for example, polystyrene foam, polyurethane foam, foam glass, basalt plate and so on, and a decorative decorative protective layer of fiber-reinforced concrete, has, in addition to heat-insulating properties, also sound-insulating properties (sound-reflecting and sound-absorbing), due to its multilayer, relative thickness and structure of the material.

The signs of the closest analogue, which coincide with the essential features of the utility model, are the presence in the slab of the insulating cladding interconnected layers: an insulating layer of heat and sound insulating material and a decorative protective layer of fiber concrete with polymer additives, sand and a cement binder.

The technical result of the utility model is to increase the life of the slab by compensating for deformations caused by external and internal stresses leading to uncontrolled deformation and destruction of the decorative protective layer of fiber-reinforced concrete to its entire depth.

The reasons that impede the achievement of the technical result when using the closest analogue are the lack of the possibility of creating compensation joints between the side surfaces of protective and decorative layers of mating plates when installing the plates on the wall enclosing structure. Heating or cooling the walls leads to a slight change in their size, which in turn creates stresses in the materials. And the larger the dimensions of the insulated walls, the greater the voltage. The structural elements of the building are connected and constantly interact with each other against the background of the fact that buildings change geometrical dimensions under the influence of changes not only in the temperature-humidity mode of operation, frame shrinkage, seismic effects, soil shifts, shrinkage of hardening concrete monolithic foundations are possible. All this causes stresses in the construction of the structure, including in the walls, although often such changes in the geometry of the elements are visually invisible.

The utility model is based on the technical task of expanding the arsenal of hardware for the construction of insulating facing slabs.

The stated technical problem is solved in that in the insulating cladding plate, including interconnected insulating layer made of heat-insulating material, and a decorative protective layer made of fiber-reinforced concrete based on sand, cement binder and polymer additives, according to the utility model, in protective decorative layer, all side surfaces along the entire thickness of the layer from the inner surface to the outer one are beveled at an angle of 80-85 ° to form a compensation indent.

According to a utility model, installation recesses are made in the decorative protective layer on the outer surface.

According to a utility model, fiber-reinforced concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, additionally contains slaked lime as a binder.

According to a utility model, fiber-reinforced concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, additionally contains sodium laureth sulfate.

According to a utility model, fiber-reinforced concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, additionally contains sodium lauryl sulfate.

Between the totality of the essential features of a utility model and the achieved technical result, there is the following causal relationship. The combination of these essential features of a utility model is a necessary and sufficient condition for achieving a technical result. The implementation of decorative protective layers with all side surfaces, which are made beveled at an angle of 80-85 ° over the entire thickness of the layer from the inner surface to the outer one, to form a compensation indent will allow the installation of rectangular plates to form expansion joints that will prevent the occurrence of cracks and the appearance of deformations in facing, will allow to remove internal stresses, eliminate the probability of destruction of the outer decorative layer and, in general, increase the duration of the operation of plates, up to longevity, since the creation of gaps will contribute to the uniform distribution of additionally arising loads (forces, stresses) by compensating for changes in the geometric dimensions (expansion, compression, twisting, shifting, bending) of the material that arise due to factors acting on fiber-reinforced concrete (or in fiber-reinforced concrete). The bevel (inclination) of all side surfaces over the entire thickness of the layer from the inner surface to the outer one at an angle of 80-85 ° (the angle is established experimentally) will allow providing sufficient compensation indentation to create a tight expansion joint between the mounted plates.

When making installation recesses in the thickness of the decorative protective layer on its outer surface, the decorative properties of the insulating cladding plate will be enhanced due to the ability to hide the heads of fasteners used to fasten the plate to the wall of the building, which in turn will protect the heads of fasteners from corrosion due to the influence of atmospheric effects and eliminate the possibility of spots from oxidation on the front surface of the plate.

With the additional introduction of slaked lime, the biocidal properties of fiber-reinforced concrete will be increased, since the high alkalinity of lime prevents the appearance and development of bacteria, various forms of fungi and microorganisms, and also reduces the shrinkage during hardening of cement stone, the increase in the plasticity (fluidity) of the solution.

With the additional introduction of sodium laureth sulfate surfactant into fiber concrete, the strength of the decorative protective layer will be increased without increasing cement consumption due to a significant decrease in the water-cement ratio.

With the additional introduction of the surface-active substance sodium lauryl sulfate into fiber concrete, the adhesion between the protective and decorative layer and sheet heat-insulating material will increase, as well as the mechanical strength of the protective and decorative layer will be increased.

The utility model meets the patentability criterion of "novelty." The prior art does not know the implementation of the compensation bevels in the decorative-protective layer of insulating cladding panels of fiber-reinforced concrete based on sand, cement binder and polymer additives.

The utility model is illustrated by graphic material, where figure 1 shows a cross section of a slab, and figure 2 shows a top view of a fragment of a surface protected by slabs with expansion joints.

The cladding insulating plate includes a layer of heat-insulating material 1, a decorative protective layer 2, a zone 3 of splicing layers 1 and 2, installation recesses 4 in the decorative protective layer 2 with its outer 5 surface and inner surface 6, side surfaces 7 of the decorative protective layer 2 are made beveled at an angle of 80-85 ° to form a compensation indentation for expansion joints 8.

The utility model is illustrated by a specific example of manufacturing an insulating cladding plate and mounting the plates on a protected surface. To prepare a decorative protective layer 2 of sand-based fibrous concrete, a binder - cement (and, if necessary, slaked lime, sodium laureth sulfate, sodium lauryl sulfate) with polymer additives, mixing water is introduced in the following order in the required amounts in the mixing mixer in the mixing mode in the following order (partially ), (lime in the form of milk of lime or lime dough, if slaked lime is to be added, while lime milk or lime dough must be aged from the moment the lime was extinguished, not m less than two weeks), an inert aggregate, for example, sand of natural or artificial origin (partially), as polymeric additives - polypropylene fiber. The ingredients are mixed, after which cement is introduced into the drum, and the resulting mixture is mixed to a state of homogeneous mass. Then the remainder of the inert aggregate, the necessary additives are introduced (for example, to accelerate or slow down the setting, antifreeze, air-entraining, hydrophobic, etc., and also, if necessary, sodium laureth sulfate and / or sodium lauryl sulfate) and the composition is mixed again until uniform . At the end, mixing water is added in the amount necessary to obtain a mixture of the desired consistency. Then proceed to the formation of layer 2 of the plate. The prepared plastic mold with the bottom surface of a given configuration and inclined side surfaces 8 at an angle α = 80-85 °, is filled with the finished mixture in the required volume and vibrated on a vibrating table for 20-30 seconds. (vibration time is determined empirically). The installation recesses 4 from the outer surface 5 of the protective and decorative layer 2 are formed, if necessary, when pouring the solution into plastic molds in which convexes corresponding to the recesses are made 4. The number of recesses 4 on each plate depends on the number of fasteners needed to fix the plate to the wall , and is standardized by the manufacturer's specifications. After that, a prepared layer of heat-insulating material 1 is placed in the mold, uniformly pressed to the surface of the mixture to form layer 2, and vibrate for 5-10 seconds. Part of the liquid mixture for forming layer 2 penetrates into the porous surface of the layer of heat-insulating material 1, forming a fusion zone 3. After molding, the finished product is sent to the place of exposure for subsequent hardening. After the formation of the mixture perform the stripping of finished products. The insulating plate is mounted on the wall enclosing structures of buildings and structures end-to-end in rows using fasteners (not shown in the figures). Recesses 4 with heads of fasteners are sealed. The joints of the mating panels are filled with elastic sealing material with the formation of expansion joints 8, then the surface of the plates is painted.

Claims (5)

1. Facing insulating plate, including interconnected insulating layer made of heat-insulating material, and a decorative protective layer made of fiber-reinforced concrete based on sand, cement binder and polymer additives, characterized in that in the protective and decorative layer all side surfaces are the entire thickness of the layer from the inner surface to the outer one is beveled at an angle of 80-85 ° to form a compensation indent. 2. The plate according to claim 1, characterized in that the installation recesses are made in the decorative protective layer on the outer surface. 3. The slab according to claim 1, characterized in that the fiber-reinforced concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, additionally contains slaked lime as a binder. 4. The slab according to claim 1, characterized in that the fiber-reinforced concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, additionally contains sodium laureth sulfate. 5. The slab according to claim 1, characterized in that the fiber-reinforced concrete based on sand, cement binder and polymer additives, from which a decorative protective layer is made, additionally contains sodium lauryl sulfate.

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